Monday, August 3, 2009

Stoichiometry calculations #1

How many grams of water and carbon dioxide are formed after the combustion of 1.275 grams of sucrose?

SOLUTION:
Recall that the chemical formula of sucrose is: $C_{12}H_{22}O_{11}$, and its molecular weight is: $MW=342.34gr/mol$.

The equation of combustion of sucrose is as follows:
$$C_{12}H_{22}O_{11}+O_2 \rightarrow CO_2+H_2O$$

This reaction must be balanced first.
Being a redox reaction, we can write the two separate reactions of oxidation and reduction:

$$\overset{0}{C_{12}}\overset{+1}{H_{22}}\overset{-2}{O_{11}}+\overset{0}{O_2} \rightarrow \overset{+4}{C}\overset{-2}{O_2}+\overset{+1}{H_2}\overset{-2}{O}$$

$$\begin{cases} \overset{0}{O_2}+4e^- \rightarrow \overset{-2}{O_2} & \quad \mbox{(x12)}\\\\ \overset{0}{C_{12}} \rightarrow 12\overset{+4}{C}+12 \cdot 4e^- \end{cases}\quad +$$
$$\rule[0.3cm]{8cm}{0.01cm} $$
$$= \quad \overset{0}{C_{12}}+12\overset{0}{O_2} \rightarrow 12\overset{+4}{C}\overset{-2}{O_2}$$

The balanced equation is:

$$C_{12}H_{22}O_{11}+12O_2 \rightarrow 12CO_2+11H_2O$$

The number of moles of sucrose contained in 1.275 grams is:

$$n_{C_{12}H_{22}O_{11}}=\frac{1.275gr}{342.34gr/mol}=0.0037mol$$

From the stoichiometry of the reaction, we know that for every mole of sucrose that is burned, you obtain 12 moles of carbon dioxide and 11 moles of water. Then we have:

$$n_{CO_2}=12n_{C_{12}H_{22}O_{11}}=0.0447mol$$

$$n_{H_2O}=11n_{C_{12}H_{22}O_{11}}=0.0410mol$$

Knowing the molecular weight of carbon dioxide (44gr/mol) and water (18gr/mol), we can calculate the weight (in grams) that is formed for each compound:

$$m_{CO_2}=44gr/mol \cdot 0.0447mol=1.9668gr$$

$$m_{H_2O}=18gr/mol \cdot 0.0410mol=0.7380gr$$



PROBLEM 21:
What mass of calcium carbonate would be formed if 248.6g of carbon dioxide were exhaled into limewater, $Ca(OH)_2$? How many grams of calcium would be needed to form that amount of calcium carbonate? Assume 100% yield in each reaction.
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Sunday, August 2, 2009

Gas formation from reaction #3

A mixture of iron (II) sulfide contains 93% of iron sulfide and 3% of metallic iron. Compute the volume (at standard condition) of gas that is formed when 10 grams of the mixture react with acid. The two reactions that occur are:
$$FeS+H^+ \rightarrow Fe^{2+}+H_2S$$
$$Fe+H^+ \rightarrow Fe^{2+}+H_2$$

SOLUTION:
The first thing to do is balance the two reactions:
$$FeS+{\color{red} 2}H^+ \rightarrow Fe^{2+}+H_2S$$
$$Fe+{\color{red} 2}H^+ \rightarrow Fe^{2+}+H_2$$

Since the 10 grams of the mixture are 97% of FeS and 3% for Fe, we can calculate the amount in grams of each component, and, knowing the molecular weight, calculate the number of moles, as follows:

$$97\%(10gr)=9.7gr(FeS)$$
$$3\%(10gr)=0.3gr(Fe)$$

Number of moles:
$$n_{FeS}=\frac{m_{FeS}}{MW_{FeS}}=\frac{9.7gr}{(55.85+32.07)gr/mol}=0.11mol$$

$$n_{Fe}=\frac{m_{Fe}}{MW_{Fe}}=\frac{0.3gr}{55.85gr/mol}=0.005mol$$

Since both the hydrogen sulfide and pure hydrogen are gas, we must calculate the number of moles of both species. Knowing the stoichiometry of the two reactions, we deduce that:

1) for each mole of Fes that reacts, it forms one mole of $H_2S$:

$$n_{H_2S}=n_{FeS}=0.11mol$$

Since a mole of gas is 22.4 liters, we have that the volume of H_2S that is formed is equal to:
$$V_{H_2S}=n_{H_2S}=0.11mol \cdot 22.4L/mol=2.464L$$

2) for each mole of iron metal that reacts, it forms a mole of hydrogen gas:

$$n_{H_2}=n_{Fe}=0.005mol$$
$$V_{H_2}=0.005mol \cdot 22.4L/mol=0.112L$$

The total volume of gas that is formed is then:

$$V_{tot}=V_{H_2S}+V_{H_2}=2.576L$$



PROBLEM 20:
how many liters of chlorine are required to transform 50.5 grams of $PCl_3$ in $PCl_5$?
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Saturday, August 1, 2009

Gas formation from reaction #2

Compute the oxygen volume (at standard conditions: 0°C, 1atm) that you need to burn 76.14gr of carbon disulfide in carbon dioxide and sulphur dioxide. Then compute the volume of carbon dioxide and sulphur dioxide and their percentage composition.

SOLUTION:
The balanced reaction that take place is:
$$CS_2(l)+{\color{red} 3}O_2(g) \rightarrow CO_2(g)+{\color{red} 2}SO_2(g)$$

For every mole of $CS_2$ that burns, we need of 3 moles of oxygen. Then:
$$n_{CS_2}=\frac{m_{CS_2}}{MW_{CS_2}}=\frac{76.14gr}{76.14gr/mol}=1mol$$

$$n_{O_2}=3n_{CS_2}$$
$$V_{O_2}=n_{O_2}\cdot22.4=67.2L$$

The volume of carbon dioxide correspond to one mole: 22.4L
The volume of sulpgur dioxide correspond to two moles: 44.8L

The percent composition of $CO_2$ and $SO_2$ is:

$$\%CO_2=\frac{n_{CO_2}}{n_{CO_2}+n_{SO_2}}\cdot100=\frac{1}{1+2}\cdot100=33\%$$

$$\%SO_2=\frac{n_{SO_2}}{n_{CO_2}+n_{SO_2}}\cdot100=\frac{2}{1+2}\cdot100=67\%$$



PROBLEM 19:
1,00 gram of a mixture of $CaCO_3$ and $MgCO_3$ gives 240mL of $CO_2$ after heating. Compute the percent composition of the mixture (remember that magnesium carbonate and calcium carbonate decompose on heating in the corresponding oxide and carbon dioxide).
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